WO2015172449A1 - Method for self-defining desktops and terminal - Google Patents

Abstract

Embodiments of the present invention provide a method for self-defining desktops and a terminal. The method comprises: a terminal receives a basic graphic used by a user for defining desktops and the number of the desktops; virtualize a polyhedron-like desktop according to the basic graphic and the number of the desktops; set a switching vector of at least two desktops of the polyhedron-like desktop and a user operation event corresponding to the switching vector; and after a user operation event is received, switch the desktop in the direction of a switching vector corresponding to the user operation event.

Description

 Method and terminal for custom desktop

 The present invention relates to the field of communications technologies, and specifically provides a method and terminal for customizing a desktop, and the related art

 At present, touch screens have been widely used in various types of mobile intelligent terminal devices, and the human-computer interaction mode is mainly touch-operated operation on the touch screen. The desktop switching of the smart terminal generally uses one-screen up and down movement and multi-screen left and right movement, and the intelligent mobile terminal desktop switching is relatively simple. Summary of the invention

 The technical problem to be solved by the embodiments of the present invention is to provide a method and a terminal for customizing a desktop, so as to realize diversity of desktop switching of the intelligent terminal.

 In order to solve the above technical problem, an embodiment of the present invention provides a method for customizing a desktop, including:

 The terminal receives the basic graphics and the number of desktops used by the user-defined desktop;

 a virtual class polyhedron desktop according to the basic graphics and the number of desktops;

 Setting a switching vector between at least two desktops of the polyhedral desktop, and a user operation event corresponding to the switching vector;

 After receiving the user operation event, the desktop is switched in the direction of the switching vector corresponding to the user operation event.

 Preferably, the foregoing method further has the following features: the virtual graph polyhedron desktop according to the basic graphics and the number of desktops includes:

 The terminal detects the number of user-defined desktops and the number of polygons of the polyhedral desktop to be virtualized. If the number of desktops defined by the user is smaller than the number of polygons of the polyhedron, the insufficient faces are complemented by the virtual surface.

Preferably, the above method further has the following features: setting at least two of the polyhedral desktops a switching vector between the desktops, and a user operation event corresponding to the switching vector, including: setting an intersection point of edges or edges between at least two desktops of the polyhedral desktop as a desktop boundary, and The intersection of the edge or edge sets the switching vector to set the mapping relationship between the switching vector and the user operation event.

 Preferably, the above method has the following features:

 The basic graphic includes one or more regular polygons.

 In order to solve the above problem, an embodiment of the present invention further provides a terminal, where the method includes: a definition module, configured to: receive a basic graphic and a desktop number used by a user-defined desktop; and a virtual module, configured to: a basic graphic and a desktop number virtual type polyhedral desktop; a setting module, configured to: set a switching vector between at least two desktops of the polyhedral desktop, and a user operation event corresponding to the switching vector;

 The switching module is configured to: after receiving the user operation event, switch the desktop in a direction of a switching vector corresponding to the user operation event.

 Preferably, the terminal further has the following features:

 The virtual module is configured to detect a virtual class polyhedron according to the basic graphics and the number of desktops in the following manner: detecting a number of user-defined desktops and a number of polygons of a polyhedron to be virtualized, such as a user-defined number of desktops is smaller than When the number of faces of a polyhedron is described, the insufficient face is filled with the virtual face.

 Preferably, the terminal further has the following features:

 The setting module is configured to: set a switching vector between at least two faces of the polyhedron, and a user operation event corresponding to the switching vector, comprising: setting at least two desktops of the polyhedral desktop The intersection point of the edge or edge is the desktop boundary, and the switching vector is set at the intersection of the edge or the edge, and the mapping relationship between the switching vector and the user operation event is set.

 Preferably, the terminal further has the following features:

 The definition module receives a user-defined basic graphic including one or more regular polygons. The embodiment of the invention further provides a computer program, comprising program instructions, when the program instruction is executed by the terminal, so that the terminal can execute the above method.

Embodiments of the present invention also provide a carrier carrying the above computer program. In summary, the embodiment of the present invention provides a method and a terminal for customizing a desktop. The user can define the shape of the desktop by itself, and can switch to multiple directions of the desktop according to the intention of the user, which can increase the efficiency of table switching and improve the user experience. . BRIEF abstract

 1 is a flowchart of a method for customizing a desktop according to an embodiment of the present invention;

 2 is a flowchart of Embodiment 1 of the present invention;

 3 is a schematic view of a regular polyhedron according to an embodiment of the present invention;

 4 is a schematic view showing a base pattern of a regular polyhedron constituting an embodiment of the present invention;

 Figure 5 is a flowchart of Embodiment 2 of the present invention;

 FIG. 6 is a schematic diagram of a terminal according to an embodiment of the present invention. Preferred embodiment of the invention

 Embodiments of the present invention will be described in detail below with reference to the accompanying drawings. It should be noted that, in the case of no conflict, the features in the embodiments and the embodiments in the present application may be arbitrarily combined with each other.

 FIG. 1 is a flowchart of a method for customizing a desktop according to an embodiment of the present invention. As shown in FIG. 1, the method in this embodiment includes the following steps:

 Step 11. The terminal receives the basic graphics and the number of desktops used by the user-defined desktop. Step 12: virtual desktop polyhedron desktop according to the basic graphics and the number of desktops;

 Step 13: setting a switching vector between at least two desktops of the polyhedral desktop, and a user operation event corresponding to the switching vector;

 After receiving the user operation event, the step 14 switches the desktop along the direction of the switching vector corresponding to the user operation event.

The mobile phone desktop of the embodiment of the present invention may be composed of a polygon, such as a positive n-gon (n is greater than or equal to 3), and the user may select the shape of the desktop (for example, a positive n-gon) that needs to be defined according to his or her preference, and the desktop. The number of polygons is concatenated into a polyhedron. Set each type of polyhedron One edge is the boundary of the desktop, and a switching vector is set on the edge, and a user operation event corresponding to the switching vector is set, such as a gesture operation: dragging the edge or clicking the edge, and switching to the other side of the edge, Complete the switch of the desktop. In other embodiments, the intersection of two ribs of the polyhedron may be set as the boundary of the desktop, and a switching vector is set at the intersection of the two edges, and a user operation event corresponding to the switching vector is set, For example, the gesture operation: Drag or click the intersection point of the two edges to switch to the other surface corresponding to the intersection point of the two edges, and complete the switching of the desktop. This can increase the efficiency of table switching and improve the user experience. If the number of user-defined desktops is not enough to form a class polyhedron, other faces can be replaced with virtual faces. The virtual surface only indicates the order of connection between the desktop and the desktop. It is not displayed on the desktop. The desktop display and switching sequence continue to switch forward according to the direction of the previously given vector.

 The above method will be described in detail below in two specific embodiments.

 In the first embodiment, the desktop is composed of a single graphic. As shown in FIG. 2, the method includes the following steps: Step 101: The terminal receives a basic graphic (positive n-sided) and a desktop number used by the user to define the desktop.

 Step 102: Calculate whether the number of desktops is greater than the number of polygons of the polyhedron according to the positive n-gon, if the number is greater than, the number of users should be set, and then go back to step 101; if not, go to step 103;

 Step 103, calculating whether the number of sets the desktop is equal to the number of faces of the polyhedron, if equal, then proceeds to step 105, if not equal, then proceeds to step 104;

 Step 104: If the number of the user-defined desktops is less than the number of the multi-faceted faces, the insufficient faces are filled with the virtual faces, and the virtual faces only indicate the connection order between the desktop and the desktop, and are not displayed on the desktop.

 Step 105: Virtually classifying a polyhedron.

 Step 106: Receive a user setting home (home) desktop.

 Step 107: Perform desktop rendering and effect setting.

 For a positive triangle (positive tetrahedron), there is a home face, and each of the other faces is the second interface. The user can switch between the three directions by ribs.

For a regular square (regular hexahedron), there is a home surface, four sides are the second interface, and only one side is the third interface. The user can switch between the four directions by ribs. By switching once On the desktop, you can reach four interfaces. Switch twice to reach the third interface.

 Since there are only five positive n-facets, Figure 3 shows: regular tetrahedron, regular hexahedron, regular octahedron, regular dodecahedron, icosahedron, and the regular hexahedron consists of squares, the dodecahedron consists of regular pentagons, regular tetrahedron, regular octahedron, The icosahedrons are all composed of regular triangles, as shown in Figure 4. Can not meet the needs of users to set desktop graphics diversification, users can also set two basic graphics to form a desktop.

 In the second embodiment, the desktop is composed of two graphics, as shown in FIG. 5, and the following steps are included: Step 201: The terminal receives two basic graphics (A-edge and B-edge) and a desktop used by the user to define the desktop. Number (T).

 Step 202: Calculate the number of basic graphics A and B edges according to two basic graphics (A-edge and B-edge) and the number of desktops (T).

 Two basic graphics (A-edge and B-edge) and the number of desktops (T) are known. Assuming that the number of vertices is V and the number of ridges is E, then the A-shaped desktop needs to be X, and the desktop with B-shape is required. It is Tx.

 Ax+( T -x)*B=E*2

 Ax+( T -x)*B=V*3

 V+ T -E=2 (Eulerian theorem)

 A, B, and T are known variables. According to the above formula, it is possible to calculate the number of desktops that need to be edged X and the B-shaped desktop is T-x.

H does not know the number of desktops: 32; desktop combination graphics: regular hexagons and regular pentagons.

 5x+(32-x)*6=V*3

 V+32-E=2 (Eulerian formula)

 According to the above equation, we get x=12. The regular pentagon is 12 and the regular hexagon is 20.

 Step 203: If the number of the user-defined desktops is less than the number of the multi-faceted faces, the insufficient faces are filled with the virtual faces, and the virtual faces only indicate the connection order before the desktop and the desktop, and are not displayed on the desktop.

Step 204: Virtually classifying a polyhedron. Step 205: Receive a user setting a home desktop.

 Step 206: Perform desktop rendering and effect setting.

 Desktop switching:

 The desktops are separated by a polyhedral-like rib, and the flipping of each face of the polyhedron indicates the switching of the desktop. The user only needs to operate on the edge, such as gesture dragging, clicking, etc., and the desktop will switch along the direction of the vector at the current gesture operation. For the virtual face that was previously filled, it is not displayed on the desktop. When the virtual surface is encountered, the switching direction is unchanged, or the direction of the user's previous user setting vector is switched until the next user-set desktop is switched.

 The user can also perform a gesture operation on a certain point on the current desktop, such as dragging or clicking, and the desktop will switch along the direction of the current vector to switch the vector until a certain edge of the desktop is encountered, and then switch to the other edge of the edge. One face. If the other side of the edge is an imaginary face, the switching direction will follow the direction of the previous vector on the imaginary surface until the user-set interface is encountered.

 The user can customize the multi-faceted desktop to change the traditional way of switching the desktop with the finger left and right, so that the user can switch the desktop in any gesture and in any direction, which can increase the desktop switching efficiency and improve the user experience.

 Of course, the desktop of the embodiment of the present invention may also be composed of two or more basic graphics, but the calculation of the required number of planes constituting the corresponding polyhedron is complicated, and will not be described in detail herein.

 FIG. 6 is a schematic diagram of a terminal according to an embodiment of the present invention. As shown in FIG. 6, the terminal in this embodiment includes:

 Definition module 21, configured to receive one or more basic graphics and desktop numbers used by the user-defined desktop;

 a virtual module 22, configured to virtualize a polyhedral desktop according to the basic graphics and the number of desktops; a setting module 23, configured to set a switching vector between at least two desktops of the polyhedral desktop, and the switching a user operation event corresponding to the vector; and a switching module 24 configured to switch the desktop in a direction of a switching vector corresponding to the user operation event after receiving the user operation event.

The virtual module 22, according to the basic graphics and the number of desktop virtual polyhedrons, includes: detecting a number of user-defined desktops and a number of polygons of a polyhedron to be virtualized, such as a user If the number of defined desktops is smaller than the number of faces of the polyhedron, the insufficient faces are filled with virtual faces.

 In a preferred embodiment, the definition module 21 receives a user-defined desktop using a basic graphic and a desktop number; the virtual module 22 is configured to detect a user-defined number of desktops and a polyhedron to be virtualized. The number of faces, if equal, is directly virtualized to the corresponding polyhedron. If it is greater than, the user is prompted to redefine. If it is less than, it is directly virtualized to the corresponding polyhedron, and the insufficient surface is filled with the virtual surface.

 In a preferred embodiment, the definition module 21 receives a plurality of basic graphics and a number of desktops by using a user-defined desktop. The virtual module 22 may be configured to determine various basics according to the basic graphics and the number of desktops. The number of graphics required; the basic graphics are virtualized into a polyhedron, and if the number of user-defined desktops is smaller than the number of polygons of the polyhedron, the insufficient faces are filled with virtual faces. The definition module 21 receives the user-defined basic graphic including one or more regular polygons, for example, a regular triangle, a square, a regular pentagon, and the like.

The embodiment of the invention further provides a computer program, comprising program instructions, when the program instruction is executed by the terminal, so that the terminal can execute the above method.

 Embodiments of the present invention also provide a carrier carrying the above computer program.

One of ordinary skill in the art will appreciate that all or a portion of the above steps may be accomplished by a program instructing the associated hardware, such as a read-only memory, a magnetic disk, or an optical disk. Alternatively, all or part of the steps of the above embodiments may also be implemented using one or more integrated circuits. Correspondingly, each module/unit in the above embodiment may be implemented in the form of hardware or in the form of a software function module. The invention is not limited to any specific form of combination of hardware and software.

The above is only a preferred embodiment of the present invention, and of course, the present invention may be embodied in various other embodiments without departing from the spirit and scope of the invention. Corresponding changes and modifications are intended to be included within the scope of the appended claims. Industrial applicability

 With the embodiment of the present invention, the user can define the shape of the desktop by itself, and can switch to multiple directions of the desktop according to the user's intention, which can increase the switching efficiency of the table and improve the user experience.

Claims

Claim

1. A method of customizing a desktop, comprising:

 The terminal receives the basic graphics and the number of desktops used by the user-defined desktop;

 a virtual class polyhedron desktop according to the basic graphics and the number of desktops;

 Setting a switching vector between at least two desktops of the polyhedral desktop, and a user operation event corresponding to the switching vector;

 After receiving the user operation event, the desktop is switched in the direction of the switching vector corresponding to the user operation event.

 2. The method according to claim 1, wherein: the virtual type polyhedral desktop according to the basic graphic and the number of desktops comprises:

 The terminal detects the number of user-defined desktops and the number of polygons of the polyhedral desktop to be virtualized. If the number of desktops defined by the user is smaller than the number of polygons of the polyhedron, the insufficient surface is filled with the virtual surface.

 3. The method of claim 1, wherein: setting a switching vector between at least two desktops of the polyhedral-like desktop, and a user operation event corresponding to the switching vector, comprising:

 Setting a point of intersection of edges or edges between at least two desktops of the polyhedral desktop as a desktop boundary, and setting a switching vector at an intersection of the edges or edges to set a mapping of the switching vector to a user operation event relationship.

 4. The method of any of claims 1-3, wherein:

 The basic graphic includes one or more regular polygons.

 5. A terminal, comprising:

 The definition module is configured to: receive a basic graphic and a number of desktops used by the user-defined desktop; a virtual module, which is set as: a virtual class polyhedron desktop according to the basic graphics and the number of desktops; a setting module, which is set as: a switching vector between at least two desktops of the polyhedral desktop of the class, and a user operation event corresponding to the switching vector;

The switching module is configured to: after receiving the user operation event, switch the desktop in a direction of a switching vector corresponding to the user operation event.

6. The terminal of claim 5, wherein

 The virtual module is configured to detect a virtual class polyhedron according to the basic graphics and the number of desktops in the following manner: detecting a number of user-defined desktops and a number of polygons of a polyhedron to be virtualized, such as a user-defined number of desktops is smaller than If the number of faces of the polyhedron is such, the insufficient face is filled with the virtual face.

 7. The terminal of claim 5, wherein

 The setting module is configured to: set a switching vector between at least two faces of the polyhedron, and a user operation event corresponding to the switching vector, comprising: setting at least two of the polyhedral desktops The intersection point of the edge or edge between the desktops is a desktop boundary, and a switching vector is set at the intersection of the edge or the edge, and a mapping relationship between the switching vector and the user operation event is set.

 8. The terminal according to any one of claims 5 to 7, wherein

 The definition module receives a user-defined basic graphic including one or more regular polygons.

9. A computer program comprising program instructions which, when executed by a terminal, cause the terminal to perform the method of any of claims 1-4.

 10. A carrier carrying the computer program of claim 9.